DE4415472A1 - Processing of electrical and electronic waste - Google Patents

Abstract

To breakdown discarded electrical and/or electronic material into specific materials, for recovery or disposal, the matter is initially sorted by size and/or type into coarse fractions to be broken down in an initial stage (11) for at least a partial mechanical sepn. of the metal and non-metal materials at the first fraction (12). The fraction (12) is passed to further stages for sepn. into different fractions according to the nature of the materials to give sorted material from the original feed. Also claimed is the use of a rotating shaft with projections, acting against a counter unit, to give a shearing action to break down the electrical and/or electronic material.

Description

The invention relates to a method for material-specific separation of electrical and / or Electronic components for the purpose of recovery or ent supply of materials.

With the ever increasing amount of no longer need Electrical and electronic components that can be scrapped and scrapped len is increasingly facing the problem of processors processing of these components, because the scrap is one Variety of expensive, recoverable materials ent who then processes it again for other purposes can, such as all metals or the same. On the other hand, the scrap also contains a large one Amount of less valuable material such as Plastics or plastic composites, which are also are partly recyclable, but partly also disposed of Need to become.

There are already procedures for treatment such scrap is known, but the chemical or are thermal in nature and in which either example way to remove the metals from the plastic on chemi is decomposed chemically or the components under Ge Only pure metal materials can be burned. However, such methods are particularly relevant disadvantageous that firstly they are very expensive, secondly Release tons of pollutants, some with it considerable effort to prepare or close in an environmentally friendly manner are disposed of, and thirdly the chemical Process yourself through the acids to be used, the only can be used conditionally until saturation and then must be disposed of again, is extremely disadvantageous.  

In addition, mechanical processes for processing Ka beln known that on a targeted separation of the Ka base sheaths are only based in the longitudinal direction of the cable. A such a method is only for such cables, however, it cannot be used for ordinary electronic waste.

The invention is therefore based on the object of a method for the treatment of electrical equipment to be scrapped and / or to create electronic components with which an on separation of the scrap into its materials easiest and is possible without pollutant generation, and for everyone Electronic waste regardless of its type or Structure can be used.

To solve this problem is in a process with the provided according to the invention, that the components only in terms of their type and / or of their structure are sorted roughly and first in one first separating device mechanically by at least part wise separation of the physical material composite between metals and non-metals in a first, non-sorted pure fraction with a predetermined material ver Bund separation guaranteeing and on the type of construction parts and / or the materials to be separated Minimum good size are crushed, and that the first sor ten-impure fraction then in another separation unit material with the formation of further fractions is specifically separated that largely as end products pure fractions can be obtained. Through this invent purely mechanical processes according to the invention are thus no time to process any externally Produces pollutants. In addition, since the scrap is only sorted roughly, d. that is, for example, le digitally equipped boards from pure cable strands  be separated - another separation of the boards does not follow - an extremely economical way of working Procedure guaranteed, since no preliminary work to lei are. Furthermore, by shredding the scrap to a minimum good size that depends on the type of goods to be separated Material depends on an almost complete material guaranteed separation of all scrap. This procedure means that, for example, thin strands of cable for detachment the all-round plastic jacket is much smaller ge be broken up to solve the physical bond, than this with only roughly assembled boards or large tra fos or chassis would be the case to break it up of the composite material, which ultimately exists who already has largely separated materials, he is required.

In order to achieve this material-specific separation, it turns out to be useful in a further embodiment of the invention moderately proven that the components in the first separation direction by means of a rotating, single, front jumping and into a suitably trained counter block engaging, preferably wedge-shaped knives ver seen wave crushed by the shearing action of the knife and that the comminuted good for the formation of the first Fraction by a waveform assigned to the wave adapted hole arranged at a predetermined distance sieve is carried out, the minimum size of the fraction is determined by the hole size of the sieve, which it according to the type of components and / or of the materials to be separated. Through this he Scrap technology according to the invention is the scrap by Shear shaft detected and pressed against the counter block, so that due to the shear effect caused in the first shear rough material separation takes place. The zer  smaller material is caused by the shaft rotation on the un indirectly guided along the perforated screen, so the material that is already the minimum required good size, passes through the perforated screen and separated becomes. The hole diameter of the sieve is advantageous speaking selected the components to be shredded so that so on the qualitative and quantitative particularity the size of the components or the material enough to break open the composite material guaranteed and therefore crucial for the recycling of valuable materials loot and thus the efficiency is responsible.

By using this special cutting technique furthermore in the next step essential to the invention reduced the goods not passing through the perforated screen through the ro tation of the shaft by means of the projecting, in correspondence Knowing the distance past the perforated screen knife changed and fed again to the shear area to in little at least one more shear gear to the minimum good size to be reduced in size, which means that the renewed or multiple shear template complete comminution even the min. not required in the first shearing process material of least material size is guaranteed.

The inventive use of sieves with spec ell defined hole diameter depending on the Ma composite, the material properties and the materi al dimensions in the components result in recognizable and predictable separation effects. Through this separation technique the material safely and dissolving the physical Bond broken. The resulting loose mixture of value, Residual and raw materials consist of after this shearing process a good size between the minimum good size through the hole diameter, and smaller good, partially  less than a millimeter. Here it turned out provides that, depending on the material specification in the shear material, approx. 50% Material parts with a grain size of less than half Hole diameter of the sieve are included.

According to the invention to optimize the separation process the components of the shear area by means of a feed device tion according to the degree of filling and / or component-specific Defined supplied, the level using a Level sensor is detected, are equally invented according to the rotation parameters of the shaft depending the type of components and / or the materials to be separated set so that by regulating the appropriate Separation parameters an optimal component-specific shredding tion is achieved. Next to it is an extended machine life guaranteed, because overloads are avoided the.

In a next method step according to the invention the first fraction formed in the first separator preferably withdrawn by means of a screw conveyor and a second separator in the form of a magnetic separator to separate the first fraction into a second, egg fraction and into a third non-ferrous one Fraction fed. Since mainly the non-ferrous Fraction that contains valuable metal materials, this is Fraction according to the invention in a third separation device Form of a sieve device to form a substantially Chen uncontaining metals and non-metals and a good size predetermined by the screening device send fourth faction and one partially a residual ver Bund, containing metals and non-metals and the fifth fraction not passing through the screening device supplied, the third separation device fiction  is a vibrating or drum sieve. Through this third Separating device thus splits the valuable third fraction in the already loose, elemen fourth fraction present and the one remaining ver Fifth parliamentary group.

This fourth fraction is then egg according to the invention fourth separator in the form of an air classifier Separation into a sixth fraction containing metals and a seventh fraction containing non-metals, the sixth and seventh fractions essentially are sorted. The fifth faction, on the other hand, is invented according to a fifth separation device in the form of a Air classifier for separation into a non-metal containing eighth fraction and in a metal with partial residual ver fed ninth fraction containing bund. In this five The separating device thus has a specific opening separation into the metalloses, only plastics or the like Eighth Frak containing and no longer to be further processed tion and into the ninth if necessary Fraction. To the metals of the ninth fraction entirely The next step will be to remove them from their remnants Process step according to the invention the ninth fraction Separation of the remaining composite, preferably via a bypass fed to the first separation device, this being the same can already happen with the fifth faction, so far from the proportion of loose non-metals in the fifth fraction is negligibly small. The feed of the fifth and possibly the ninth fraction to the first Separating device takes place depending on the invention on the degree of filling of the first separation device and / or on the Feeder, the feeder being a guarantee optimal shear performance, if necessary the fraction feed is controlled.  

As an alternative to feeding the fifth or ninth fraction to The first separator, these fractions can fiction according to a sixth feed device for separation of the remaining composite are fed via a bypass, wherein in this sixth separator, which in further inven dungsausbildung corresponding to the first separation device can be carried out so that they also through the spe The main shear technique breaks the rest of the composite, a tenth Fraction is formed. The tenth faction will according to the invention a seventh separating device, in particular another a wind sifting, fed to the metals therein separate from the rest of the material. This wind sighting can, like also all previous, in a zigzag wind classifier Alternatively, however, the tenth fraction can again be fed to the fourth separation device.

Furthermore, it has proven to be expedient according to the invention if the fifth and possibly the ninth fraction with one of the first and possibly the sixth Separating device in the bypass upstream cooling device be cooled to embrittlement, so that a easier separation of the bond between metal and Non-metal is possible.

Further advantages, features and details of the invention result from the example described below as well as based on the drawings. Show:

Fig. 1 is a sectional view of the schematically illustrated first separating means,

Fig. 2 is a plan view of the first separating means of Fig. 1 in the direction of arrow II in Fig. 1,

Fig. 3 shows the perforated screen below the shear shaft with different hole sizes, and

Fig. 4 is a flow chart of the method according to the invention.

Fig. 1 shows the first separation device 1 , consisting of a hopper 2 for feeding indicated material, and a shaft 3 arranged below, which is rotatable about the axis of rotation 4 and on its outer circumference with shear blades 5 in a staggered arrangement (see Fig. 2) is busy. This shear knife 5 engage in a counter block 6 in corresponding exceptions 7 , whereby the both by the weight of the material and a feed device 8 brought up components are crushed by the shear effect generated by the engagement of the knives 5 in the recesses 7 . Here, the shear blades 5 are arranged offset from one another, as indicated schematically in FIG. 2, but both the design of the knives and their arrangement and the specific formation of the counter block 6 and its recesses 7 are variable. Below the shaft 3 , a perforated screen 9 was arranged in a predetermined From, which has the shape of the shaft 3 . The sieve 9 is arranged so close to the shaft that the shear blades 5 are passed at a very close distance to the side of the perforated sieve 9 facing the shaft 3 . This means that the shear process does not shred material corresponding to the material-specific hole size, which consequently cannot pass through the perforated screen 9 as well, is conveyed along by means of the shear knife 5 on the perforated screen 9 , moved around and again fed to the filling material area, so that after some Time he comes again in shear template and can be shredded to the required minimum size, which corresponds to the hole diameter selected for the component.

A detailed view of the perforated screen is shown in FIG. 3. It can be seen that the holes 10 of the screen 9 are circular in the example shown. The divided into three sections 9 a, 9 b and 9 c screen 9 is provided in all sections with holes 10 of the same diameter, in the example shown, however, the hole diameter 10 decreases from area 9 a to area 9 c to the various usable To represent hole diameter. Different sieves of different diameters are used in accordance with the components to be machined, since the minimum size of the hole, which is essential for the method according to the invention and on which the material yield and thus the efficiency is crucially dependent, is predetermined by the hole size. For example, with coarse material, such as a large chassis or the like, a perforated screen with a large hole diameter is selected, but if, for example, individual components such as relays or contactors or circuit boards are to be crushed, the medium hole size can be selected, for example, the smallest hole size is recommended for cables .

The smaller the hole diameter chosen, of course, the higher the degree of separation of the individual materials, since the material passing through the perforated screen has already been comminuted accordingly. However, a reduction in the hole diameter is limited in terms of process technology and cannot usually be reduced to the minimum value required for the optimal separation effect, which ensures almost complete separation, with economic concerns also playing a role here. However, this is taken into account by the resubmission of the coarse material in the shear area, which ensures that the material is correspondingly reduced in size, and experiments have shown that only a small part has the minimum good size, however, the majority of the shear material is significantly smaller than the perforated screen diameter. As a result, with the described shearing device, the most extensive material breakdown can be achieved in the first separation process. The material passing through the perforated screen 9 , ie the first fraction, is then conveyed by means of a screw conveyor 40 to the subsequent separating device.

The exact procedure is shown in Fig. 4. The component is first fed (arrow A) into the first separating device 11 . The fill level is detected both with regard to the supply of components and the actual operation of the separating device 11 and the corresponding feed taking place in the shear area is controlled. After crushing the components in the first separating device 11 , the first fraction 12 is obtained, which is fed to a second separating device 13 , a magnetic separator (arrow B). This magnetic separator separates the first fraction into a second, ferrous fraction 14 and a third, non-ferrous fraction 15 . The iron-containing fraction, which experience has shown that there is only a residual composite made of plastic of approx. 2%, does not have to be treated further and is consequently fed to a container 16 . The third fraction 15, on the other hand, is fed to a third separating device, a screening device 17 (arrow C). In this sieving device, for example a vibrating or drum sieve, the third fraction is separated into a fourth, non-bonded fraction 18 , which passes through the sieve as a result of sufficient good size, and a fifth, coarse and partly residual fraction 19 . The fourth fraction 18 is fed to a fourth separation device 20 , namely an air classifier, preferably a zigzag air classifier (arrow D). Since the fourth fraction contains 18 and only elementary, non-bonded material, in the fourth separation device 20 a separation into a sixth fraction containing only the metals 21 and a seventh fraction containing only the non-metals, i.e. plastics or base material 22 take place, the then sorted sixth and seventh fractions being placed in respective containers 23 , 24 .

The fifth fraction 19, on the other hand, which contains material which does not pass through the screening device, that is to say too coarse and has a residual composite, requires further treatment. This can vary depending on the composition of the fifth fraction 19 . If the fifth fraction 19 contains only a small proportion of loose, coarse non-metals, i.e. plastics, it is not necessary to separate them and the fifth fraction 19 can be fed immediately to the first separating device 11 (arrow E), so that in this first separating device 11 the material is shredded again. In order to improve the separation process, the fifth fraction 19 of a cooling device 25 can be fed before being fed to the first separating device 11 (arrow E '), in which the material becomes brittle and therefore can subsequently be more easily shredded.

As a rule, however, the non-metal content of the fifth fraction 19 is large and requires its separation. Therefore, the fifth fraction 19 is fed to a fifth separating device 26 (arrow F), the fifth separating device 26 again being a wind classifier. This separates into the eighth fraction 27 , which contains only non-metals, which is subsequently led into a container 28 , and into the ninth fraction 29 , which contains metals with the partial residual compound.

There are also several options for the further treatment of the ninth fraction 29 . If the valuable metal content is low and further treatment is not worthwhile, this can be fed to a container 30 immediately. Alternatively, the ninth fraction 29 is normally fed again to the first separating device 11 (arrow G) in order to be comminuted therein. Likewise, the ninth fraction 29 can be fed to facilitate the separation in the downstream separating device of the cooling device 25 (arrow H), in which the plastic material in turn becomes brittle and can accordingly be separated from the metal more easily. The material cooled in this way is then again delivered to the first separating device 11 , although it can sometimes prove disadvantageous that the momentarily cold material is warmed again on the way to the new shear template and the cooling effect is lost. Therefore, it has proven to be expedient if the material cooled in the cooling device 25 is fed to the ninth fraction 29 of a separate sixth separating device 31 (arrow H '), which is connected directly downstream of the cooling device 25 . In this sixth separating device 31 , which is constructed in accordance with the first separating device 11 and uses the same shear technology according to the invention, the separation of the ninth fraction 29 , which is facilitated by the cooling of the material, then takes place, forming the tenth fraction 32 . This fraction 32 can now either be fed to a separate seventh separating device 33 (arrow J), with this seventh separating device 33 again being able to hold an air classifier and after which the material is deposited in respective containers 34 , 35 . Alternatively, the separated material can be fed again to the fourth separating device 20 , in which the compound which is present without a connection and has the same parameters as the material of the tenth fraction 32 and the material of the fourth fraction 18 is separated (arrow K) in order to be separated and in there the respective containers to be brought.

4 more alternatives in terms of material guide Furthermore, FIG. Removed. So the cooling device 25 supplied fifth fraction 19 (arrow E '), if this is already deducted here, instead of the sixth separating device 31 are fed to it (arrow E''). The same can be done without interposing the cooling device 25 (arrow E '''). In addition, the ninth fraction 29 can be directly supplied to the sixth separating device 31 without being carried out by the cooling device 25 (arrow H '').

Claims (19)

1. Process for the material-specific separation of electrical and / or electronic components to be scrapped for the purpose of recovery or disposal of the materials, characterized in that the components are only roughly sorted in terms of their type and / or their construction and initially in a first separating device ( 11 ) mechanically by at least partially separating the physical material combination between metals and non-metals into a first, non-varietal fraction ( 12 ) with a predetermined number, which ensures separation of the material composite and is dependent on the type of components and / or the materials to be separated, depending on the minimum good size are crushed, and that the first, non-varietal fraction ( 12 ) is then separated in further separation devices with formation of further fractions in such a material-specific manner that largely pure fractions are obtained as end products. 2. The method according to claim 1, characterized in that the components in the first separating device ( 1 , 11 ) by means of a rotating, with individual, projecting and engaging in a correspondingly designed counter block ( 6 ) engaging, preferably wedge-shaped knives ( 5 ) shaft ( 3 ) crushed by the shearing action of the knives ( 5 ), and that the zer smaller material to form the first fraction ( 12 ) through a shaft ( 3 ) associated with the waveform adapted and arranged at a predetermined distance perforated screen ( 9 ) is, the minimum size of the fraction ( 12 ) is determined by the hole size of the sieve ( 9 ). 3. The method according to claim 2, characterized in that the hole size of the perforated screen ( 9 ) is selected according to the type of components and / or the materials to be separated. 4. The method according to claim 2 or 3, characterized in that the comminuted, the perforated screen ( 9 ) not pas-based material by the rotation of the shaft ( 3 ) by means of the projecting, at a corresponding distance from the perforated screen ( 9 ) passing knife ( 5 ) conveyed and fed again to the shear area in order to be shredded to the minimum good size in at least one further shear cycle. 5. The method according to any one of claims 2 to 4, characterized in that the components of the shear area by means of a feed device ( 8 ) according to the degree of filling and / or component-specific are supplied, the level being detected by means of a level sensor. 6. The method according to any one of claims 2 to 5, characterized in that the rotation parameters of the shaft ( 3 ) are set depending on the type of components and / or the materials to be separated. 7. The method according to any one of the preceding claims, characterized in that the first fraction ( 12 ) from the first separation device ( 11 ) is preferably withdrawn by means of a screw conveyor ( 40 ) and a second separation device ( 13 ) in the form of a magnetic separator for separation the first fraction ( 12 ) is fed into a second, ferrous fraction ( 14 ) and into a third, non-ferrous fraction ( 15 ) (B). 8. The method according to claim 7, characterized in that the third fraction ( 15 ) of a third Trenneinrich device ( 17 ) in the form of a sieve device to form an essentially composite metals and non-metals containing and a predetermined size of the sieve device having fourth fraction ( 18 ) and one partially having a residual composite, which contains metals and non-metals and does not pass through the screening device fifth fraction ( 19 ) is fed (C). 9. The method according to claim 8, characterized in that the separation of the third fraction ( 15 ) takes place in a vibrating or drum screen. 10. The method according to claim 8 or 9, characterized in that the fourth fraction ( 18 ) of a fourth separating device ( 20 ) in the form of an air classifier for separation into a metal-containing sixth fraction ( 21 ) and a non-metal-containing seventh fraction ( 22 ) is supplied (D), the sixth and seventh fractions ( 21 , 22 ) being essentially single-variety. 11. The method according to any one of claims 8 to 10, characterized in that the fifth fraction ( 19 ) of a fifth separating device ( 26 ) in the form of an air separator for separation into a non-metal-containing eighth fraction ( 27 ) and in a metal with a partial residual composite containing ninth fraction ( 29 ) is fed (F). 12. The method according to any one of claims 8 to 11, characterized in that the fifth and optionally the ninth fraction ( 19 , 29 ) for separating the Restverbun preferably via a bypass (E, G) of the first separation device ( 11 ) are supplied. 13. The method according to claim 12, characterized in that the fifth and optionally the ninth fraction ( 19 , 29 ) to the first separation device ( 11 ) in dependence on the degree of filling of the first separation device ( 11 ) and / or from the feed device ( 8 ) supplied who the, and that optionally the feed device ( 8 ) is controlled according to the fraction feed. 14. The method according to any one of claims 8 to 11, characterized in that the fifth and optionally the ninth fraction ( 19 , 29 ) of a sixth separating device ( 31 ) for separating the remaining composite to form a tenth fraction ( 32 ) via a bypass be led (E ′ ′ ′, H ′ ′). 15. The method according to claim 14, characterized in that the sixth separating device ( 31 ) is designed according to the first separating device ( 11 ), so that the fifth and optionally the ninth fraction ( 19 , 29 ) corresponding to the way of separating the first separating device ( 11 ) is crushed. 16. The method according to any one of claims 12 to 15, characterized in that the fifth and optionally the ninth fraction ( 19 , 29 ) by means of one of the first and optionally the sixth separation device ( 11 , 31 ) upstream in the bypass cooling device ( 25 ) to Ma embrittlement can be cooled (H, H ′, E ′, E ′ ′). 17. The method according to any one of claims 14 to 16, characterized in that the tenth fraction ( 32 ) of a seventh separating device ( 33 ), in particular an air classifier or optionally the fourth separating device ( 20 ) is fed (J, K). 18. The method according to any one of claims 10 to 17, characterized in that the fourth and optionally the fifth and tenth fraction ( 18 , 19 , 32 ) is separated in a zigzag air classifier. 19. Use a separating device with a rotate the, with knives, which are trained accordingly counter block ensuring a Scherwir intervention, occupied shaft to cut the physical material composite from to scrap tendency electrical or electronic components in the context of Recovery or disposal of materials.